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ID 116

Investigation of the liquid accumulation characteristics in planar prefliming airblast atomization

Geoffroy Chaussonnet
Karlsruhe Institute of Technology - Institute of Thermal Turbomachinery
Germany

Thomas Laroche
Karlsruhe Institute of Technology - Institute of Thermal Turbomachinery
Germany

Christian Lieber
Karlsruhe Institute of Technology - Institute of Thermal Turbomachinery
Germany

Simon Holz
Karlsruhe Institute of Technology - Institute of Thermal Turbomachinery
Germany

Rainer Koch
Karlsruhe Institute of Technology - Institute of Thermal Turbomachinery
Germany

Hans-Jörg Bauer
Karlsruhe Institute of Technology - Institute of Thermal Turbomachinery
Germany

 

Abstract:

The phenomenon of prefliming airblast atomization is investigated by means of shadowgraphy. The focus is on the liquid accumulation, which is attached to the trailing edge in the wake region of the prefilmer. The prefilmer is planar to facilitate the measurements, and the trailing edge thickness is 240µm. The investigated liquid is a kerosene surrogate (Shellsol D70). The operating parameters are varied with a bulk gas velocity ranging from 20 to 100 m/s and a surface volumetric liquid flow rate ranging from 20 to 120 mm2/s. In order to statistically investigate the liquid accumulation, it is virtually split into several atomizing cells. Each cell consists of a single ligament and a surrounding liquid part. Different characteristic lengths of the atomization cells are extracted by a post-process tool developed in-house. The distribution of these length scales are well described by a gamma function, whose scale parameter (m) is proportional to a Weber number based on the trailing edge thickness (We_te). However, it is observed that the parameter m also varies with the liquid flow rate, independently of We_te. A two-step mechanism is proposed for the dynamics of the liquid accumulation, leading to the expression of a new length scale, which combines We_te and the liquid flow rate. It is demonstrated that this new length scale is proportional to all types of lengths extracted from the experiment, independently of the varied parameters. Hence, this new characteristic length is a good candidate for predicting the length scale of the accumulation in more general configurations.